KR101147179B1 - Inverter circuit, backlight, and lcd - Google Patents

Abstract

Provided is an inverter circuit capable of realizing a large backlight without increasing the number of balance transformers in accordance with a balance circuit. The inverter circuit includes a plurality of inverter transformers and a plurality of balance transformers which provide an AC high voltage in reverse phase to each other. At intervals the cold cathode tubes are connected in series with the primary windings of the balance transformer, respectively, and the secondary windings of the plurality of balance transformers each form a closed loop connected in series.

Back light, inverter transformer, cold cathode tube, fluorescent lamp

Description

Inverter circuit, backlight and liquid crystal display {INVERTER CIRCUIT, BACKLIGHT, AND LCD}

1 is a block diagram of a liquid crystal display device 100 having an inverter circuit and a backlight according to an embodiment of the present invention;

2 is an exploded perspective view of a backlight unit in a liquid crystal display device 100 having an inverter circuit and a backlight according to an embodiment of the present invention;

3 is a functional block diagram of a liquid crystal display (100) having an inverter circuit and a backlight according to an embodiment of the present invention;

4 is a view showing the structure of a conventional cold cathode tube 300;

5 is a schematic circuit diagram of an inverter circuit and a backlight;

6 is a schematic circuit diagram of an inverter circuit and a backlight according to an embodiment of the present invention;

7 is a schematic circuit diagram of an inverter circuit and a backlight according to an embodiment of the present invention;

8 is a view showing an example in which the slit 430 is used for the electrode substrate 153 on the high voltage side according to one embodiment of the present invention;

9 is a schematic circuit diagram of a conventional inverter circuit.

Explanation of symbols on the main parts of the drawings

100 LCD 110 Display Unit

111 Liquid crystal display panel 112 Data circuit

113 gate circuit 114 data circuit tape board

116 TFT Board

117 CF board 120 Back light unit

121 Reflective plate 122 Cold cathode tube

123 Optical Sheet 130 Storage Container

131 bottom 132 side wall

140 Top chassis 400 High voltage side circuit

401 inverter transformer 402 resistor

403 inverter transformer 404 resistor

406 Low Voltage Side Circuit

407_1, 407_2, ..., 407_n / 2 ms balance transformer

410 High voltage side circuit 411 Inverter transformer

412 Resistor Element 413 Inverter Transformer

414Ω resistance element 416Ω Low voltage side circuit

417_1, 417_2, ..., 417_n / 2 Balanced transformer

419 Closed Loop 420 High Voltage Side Circuit

421 inverter transformer 430 slit

The present invention relates to an inverter circuit, and more particularly, to an inverter circuit for driving a backlight of a liquid crystal display.

BACKGROUND ART In general, liquid crystal displays have excellent characteristics such as low voltage driving, low power consumption, light weight, and thinness, and are widely used as display devices such as monitor devices and television receivers in personal computers, and the demand for enlargement thereof is increasing in recent years.

The liquid crystal display device is composed of a backlight and a liquid crystal display unit disposed in front of the backlight, the backlight supplies light to the display panel, the liquid crystal display unit modulates the light supplied from the backlight, It is displayed as an image.

The backlight has a reflector, a light source and an optical sheet, and supplies light to the display unit by applying a current to the light source.

Background Art A cold cathode tube (discharge tube) has conventionally been used for backlight of a liquid crystal display. The cold cathode tube has two terminals and emits light when an alternating voltage of several thousand volts is applied to both terminals. An AC power supply of 100 V is supplied from the outside to the liquid crystal display which is one of home appliances. In addition, in the liquid crystal display, an AC voltage supplied from outside is converted into a DC voltage at one time, and the primary side of the inverter transformer is pulsed by the DC voltage, and the AC voltage boosted by the secondary side of the inverter transformer is used. The method of driving a cold cathode tube is employ | adopted. In this manner, a circuit for pulse driving the primary side of the inverter transformer is an inverter circuit.

As for the backlight of the liquid crystal display, many methods of lighting one cold cathode tube with one inverter transformer have conventionally been employed. However, in accordance with the large screen of the liquid crystal display, a plurality of cold cathode tubes are connected in parallel to connect the inverter transformer. A plurality of cold cathode tubes are driven by applying a high voltage.

9 is a conventional inverter circuit for driving a plurality of cold cathode tubes by connecting a plurality of cold cathode tubes in parallel and applying a high voltage of an inverter transformer. Reference numeral 1000 is an inverter transformer, and 1001 is a resistance element. 1002_1 to 1002_n are cold cathode tubes, and AC voltages boosted on the secondary side of the inverter transformer 1000 are respectively applied. The resistance element 1001 becomes a resistance for tube current detection flowing through the cold cathode tubes 1002_1 to 1002_n. Reference numeral 1004 denotes a balance circuit and has balance transformers 1003_1 to 1003_n. The balance circuit 1004 is connected in series to the cold cathode tubes 1002_1 to 1002_n.

The primary sides of the balance transformers 1003_1 to 1003_n are connected in series between the cold cathode tubes 1002_1 to 1002_n and the ground GND, respectively. The secondary sides of the balance transformers 1003_1 to 1003_n are each connected in series to form a closed loop. As described above, since the secondary side of the balance transformers 1003_1 to 1003_n forms a closed loop, the current is flowing in the closed loop flows in common to the secondary side of the balance transformers 1003_1 to 1003_n, and the balance transformer 1003_1 to 1003_n The balances of the currents iL1, iL2, ..., iLn flowing through the cold cathode tubes 1002_1 to 1002_n on the primary side of the are maintained.

However, in the conventional inverter circuit as shown in Fig. 9, a balance transformer equal to the number of cold cathode tubes is required. In order to meet the demand for larger backlights due to the larger size of liquid crystal displays, the number of cold cathode tubes must be increased, and as the cold cathode tubes increase, the number of balance transformers increases, and as a result, the cost is very high. It becomes high. In addition, in order to enlarge a backlight, the board | substrate which mounts a balance circuit is also required to be enlarged, As a result, a cost becomes very high.

Accordingly, an object of the present invention is to provide an inverter circuit capable of realizing a large backlight without increasing the number of balance transformers in a balance circuit in view of the above problems.

Embodiments of the present invention provide an inverter circuit, a backlight, and a liquid crystal display.

Inverter circuit according to an embodiment of the present invention comprises: a plurality of inverter transformer for supplying the alternating current AC high voltage; And a plurality of balance transformers, wherein the inverter transformer supplies an alternating high voltage in phase for every n plurality of cold cathode tubes, and the cold cathode tubes are in series with the primary windings of the balance transformers at intervals of one of the cold cathode tubes. The secondary windings of the plurality of balance transformers are connected to each other in series to form a closed loop.

In this embodiment, the inverter transformer can supply an alternating high voltage in phase for each of the plurality of cold cathode tubes.

In this embodiment, the plurality of inverter transformer may be two.

In this embodiment, the inverter transformer includes one primary winding and two secondary windings, and the two secondary windings may be arranged such that the AC high voltages are reverse polarity with each other.

The backlight according to the embodiment of the present invention includes: a plurality of cold cathode tubes; A plurality of inverter transformers for supplying alternating high-phase AC high voltages; And a plurality of balance transformers, wherein the inverter transformer supplies alternating high voltage in phase for every n plurality of cold cathode tubes, and the cold cathode tubes are in series with the primary windings of the balance transformers at intervals of one of the cold cathode tubes. The secondary windings of the plurality of inverter transformers are connected in series to form a closed loop.

In this embodiment, the inverter transformer may provide an alternating high voltage in phase for every two cold cathode tubes.

In this embodiment, the plurality of inverter transformer may be two.

In this embodiment, the inverter transformer includes one primary winding and two secondary windings, and the two secondary windings may be arranged such that the AC high voltages are reverse polarity with each other.

In this embodiment, the terminals for providing an alternating-phase high voltage for every n cold cathode tubes may be spaced apart by slits.

A liquid crystal display device according to an embodiment of the present invention comprises: a display unit having a liquid crystal panel, a data circuit and a gate circuit connected to the liquid crystal panel; A backlight including a plurality of cold cathode tubes, a plurality of inverter transformers, and a plurality of balance transformers; And a storage container and a top chassis for accommodating the display unit and the backlight, wherein the inverter transformer supplies an alternating high voltage in phase for every n plurality of cold cathode tubes, and the cold cathode tubes are spaced at one interval between the cold cathode tubes. The primary windings of the balance transformer may be connected in series, and the secondary windings of the plurality of inverter transformers may be connected in series to form a closed loop.

In this embodiment, the inverter transformer may provide an alternating high voltage in phase for every two cold cathode tubes.

In this embodiment, the plurality of inverter transformer may be two.

In this embodiment, the inverter transformer includes one primary winding and two secondary windings, and the two secondary windings may be arranged such that the AC high voltages are reverse polarity with each other.

In this embodiment, the terminals for providing an alternating-phase high voltage for every n cold cathode tubes may be spaced apart by slits.

The use of the liquid crystal display device is very suitable as a liquid crystal monitor and a liquid crystal TV.

According to the inverter circuit and the backlight of the present invention, even when the number of cold cathode tubes (discharge tubes) is increased, the number of balance transformers can be limited to half the number of cold cathode tubes, so that the backlight can be enlarged.

According to the inverter circuit and the backlight according to the embodiments of the present invention, since the phases of the alternating voltage applied to the adjacent cold cathode tubes are alternately inverted for each of a plurality of lines, it is not only possible to suppress noise but also to alter the phase of the same phase. It is not necessary to consider the insulation distance between the cold cathode tubes of a plurality of lines to which voltage is applied, and the wiring can be made compact.

 BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features, and advantages of the present invention will become more readily apparent from the following description of preferred embodiments with reference to the accompanying drawings.

Although terms such as first, second, third, and the like are used to describe various configurations in various embodiments of the present specification, these configurations should not be limited by these terms. Also, these terms are only used to distinguish one configuration from another.

EMBODIMENT OF THE INVENTION Embodiment of this invention is described below with reference to drawings. However, this invention can be implemented in many other forms and is not interpreted limited to description of embodiment and Example shown below. In addition, in the drawings referred to in the present embodiment and the first embodiment, the same reference numerals are used for the same portions or portions having the same functions, and repetitive description thereof will be omitted.

1 schematically shows a liquid crystal display (also referred to as a "liquid crystal display") 100 in which an inverter circuit and a backlight are combined according to an embodiment of the present invention. Referring to FIG. 1, the liquid crystal display device 100 includes a display unit 110, a backlight unit 120, a storage container 130 for storing these, and a top chassis 140.

The display unit 110 includes a liquid crystal display panel 111 displaying an image, a data circuit 112 and a gate circuit 113 which provide a driving signal for driving the liquid crystal display panel 111. The data circuit 112 and the gate circuit 113 are electrically connected to the liquid crystal display panel 111 via the data circuit tape substrate 114 and the gate circuit tape substrate 115, respectively.

The liquid crystal display panel 111 is a thin film transistor (hereinafter referred to as "TFT") substrate 116 and a color filter (hereinafter referred to as "CF") disposed opposite the TFT substrate 116. And liquid crystal disposed between these substrates.

The TFT substrate 116 is not particularly limited as long as it can form a TFT and an electrode. For example, a transparent glass substrate can be suitably used. On the TFT substrate 116, a plurality of gate electrodes and a plurality of data electrodes arranged to intersect the gate electrodes, and a plurality of gate electrodes and data electrodes arranged near each intersection point and connected to these gate electrodes and data electrodes TFT and a pixel electrode provided in connection with each of the plurality of TFTs are provided. The common electrode provided corresponding to the pixel electrode may be formed on the TFT substrate 116 or may be formed on the CF substrate 117.

The CF substrate 117 is also not particularly limited as long as it can form CF, similarly to the TFT substrate 116. For example, a transparent glass substrate can be suitably used. CF formed on the CF substrate can be realized by arranging an organic layer containing a dye that transmits red (R), green (G), and blue (B) colors corresponding to each pixel electrode of the TFT substrate. The liquid crystal display device 100 is provided with, for example, a backlight unit 120 on the back side, and adjusts the light from the backlight device using an optical change by the liquid crystal display panel to display the image as a TFT substrate ( 116 and both of the CF substrates 117 are preferably transparent substrates.

The storage container 130 includes a bottom surface 131 and sidewalls 132 provided on a side where the bottom surface 131 ends, and accommodates the display unit 110, the backlight device 120, and the like. That is, the storage container 130 is coupled to the top chassis 140 to fix the display unit 110 and the like stored therein, and also prevent damage due to external impact.

2 is an exploded perspective view of the backlight unit 120 of the liquid crystal display device 100. The backlight unit 120 includes a reflecting plate 121, a plurality of discharge tubes 122 disposed substantially in parallel on the reflecting plate 121, an optical sheet 123 disposed above the plurality of discharge tubes, And a plurality of second electrodes 154 provided in each of the plurality of discharge tubes 122. Moreover, the some 2nd electrode 154 is formed on the electrode substrate 155, and the balance circuit mentioned later is formed on the electrode substrate 155. FIG. The discharge tube 122 is not particularly limited thereto, and a cold cathode tube may be used. Hereinafter, an example in which a cold cathode tube is used as the discharge tube will be described.

An inverter circuit 150 is connected to the backlight unit 120, and in this embodiment, the inverter circuit 150 is disposed outside the storage container 130. The inverter circuit 150 may be provided inside the backlight unit 120.

The optical sheet 123 is provided to improve the characteristics of the light supplied by the backlight unit 120, and the optical sheet 123 may be, for example, a diffusion sheet for diffusing light, and collects light. It may be a prism sheet for. The number of cold cathode tubes 122 in the backlight unit 120 is not particularly limited, but is preferably 10 or more, more preferably 14 or 16.

3 is a functional block diagram of a liquid crystal display device 100 having an inverter circuit and a backlight according to an embodiment of the present invention. Referring to FIG. 3, the liquid crystal display device 100 includes a power supply circuit power supply unit 10, a liquid crystal panel driver circuit driver 20, and a backlight unit 50.

Power supply circuit The power supply section 10 converts the output voltage of the AC / DC rectifying section 12 and the AC / DC rectifying section 12 connected to the AC plug 11 where 100 V AC power is supplied to the liquid crystal panel. And a DC / DC converter 13 for supplying a predetermined voltage to the driving circuit driver 20 and the backlight driver 50, respectively.

The liquid crystal display panel driver circuit driver 20 includes a gate driver 24 for driving a gate line of the liquid crystal display panel 111, a data driver 25 for driving a data line, a liquid crystal panel 26 coupled thereto, and data. Vcom generator 22, gamma voltage generator 23, and gate driver 24 for supplying various voltages to the driver. Vcom generation section 22. and a DC / DC converter 21 for supplying DC power to the gamma voltage generator 23.

The backlight unit 50 is a cold cathode tube backlight unit 30 composed of a plurality of cold cathode tubes, and an inverter unit 90 for supplying a high frequency high voltage having an amplitude of about 2 kV to the cold cathode tube backlight unit 30. It is composed. The inverter circuit of the present invention is related to this inverter section 90. Moreover, the backlight of this invention is related with the backlight 50 which has the cold cathode tube backlight part 30 and the inverter part 90 which consist of a some cold cathode tube.

First, the structure of a cold cathode tube is demonstrated with reference to FIG. 4 schematically shows the structure of a general cold cathode tube 301. Referring to FIG. 4, the cold cathode tube 301 is composed of a glass tube 326 in which an encapsulating gas 325 is sealed therein, and both ends of the glass tube 326 have lead wires 321 and electrodes 328. These are arranged, respectively. The phosphor 322 is coated inside the glass tube 326. Mercury 323 is enclosed in the glass tube 326. When a high frequency high voltage is applied to the positive electrode 328, electrons pass through the gas tube, and mercury excited by the electrons emits ultraviolet rays 324. When the ultraviolet ray 324 is irradiated onto the phosphor 322, the phosphor emits white visible light to the outside. In this embodiment, this cold cathode tube 301 is used for the cold cathode tube 122 of the backlight unit 50.

Next, reference is made to FIG. 5. In FIG. 5, the schematic circuit block diagram of the inverter circuit and backlight which the present inventors discovered about the process leading to development of the inverter circuit and backlight of this invention is shown. As shown in FIG. 5, this inverter circuit has a high voltage side circuit 400 and a low voltage side circuit 406. The high voltage side circuit 400 has an inverter transformer 401 and a resistance element 402 connected to the secondary side thereof, an inverter transformer 403 and a resistance element 404 connected to the secondary side thereof. The low voltage side circuit 406 has a plurality of (n / 2) balanced transformers 407_1, 407_2, ..., 407_n / 2.

Referring to Fig. 5, the backlight has a plurality (n) of cold cathode tubes 122_1, 122_2, ..., 122_ (n-1), 122_n. Here, although n = 14 and the number of cold cathode tubes 122 was 14, it is not limited to this. AC voltages boosted by the secondary sides of the inverter transformers 401 and 403 of the high voltage side circuit 400 are applied to the cold cathode tubes 122_1 to 122_n, respectively. The resistance elements 402 and 404 become resistances for detecting tube current flowing through the cold cathode tubes 122_1 to 122_n.

In the inverter circuit and the backlight shown in Fig. 5, adjacent cold cathode tubes, that is, cold cathode tube 122_1 and cold cathode tube 122_2, cold cathode tube 122_2 and cold cathode tube 122_3, ..., cold cathode tube 122_ (n-1) and cold A high voltage of reverse polarity is applied to the cathode tube 122_n, and low noise is caused by differential driving of the so-called cold cathode tube.

The adjacent cold cathode tube 122_1 and the cold cathode tube 122_2 are connected in series with the primary side (primary coil) of the balance transformer 407_1 in the low pressure side circuit 406. Similarly, the adjacent cold cathode tube 122_3 and the cold cathode tube 122_4 are connected in series with the primary side (primary coil) of the balance transformer 407_2 in the low pressure side circuit 406. Similarly, the adjacent cold cathode tube 122_ (n-1) and cold cathode tube 122_n are connected in series with the primary side (primary coil) of the balance transformer 407_n / 2 in the circuit 406. Thus, the structure which the adjacent cold cathode tube is connected in series with the primary side (primary coil) of one balance transformer is employ | adopted. In addition, the secondary side (secondary coil) of all the balance transformers 407_1, 407_2, ..., 407_n / 2 is connected in series, respectively, and forms the closed loop.

Thus, since the secondary side (secondary coil) of the balance transformers 407_1, 407_2, ..., 407_n / 2 forms the closed loop 409, the current is flowing through this closed loop 409 is It flows in common to the secondary side (secondary coil) of the lance transformers 407_1, 407_2, ..., 407_n / 2, and the primary side of the balance transformers 407_1, 407_2, ..., 407_n / 2 (primary coil) The balances of the currents iL1, iL2, ..., iLn flowing through the cold cathode tubes 122_1, 122_2, ..., 122_ (n-1), 122_n connected to are maintained.

In the inverter circuit and backlight shown in Fig. 5, the number of balance transformers is half the number of cold cathode tubes.

As described above, in the inverter circuit and the backlight shown in Fig. 5, since the phases of the high voltage applied to the adjacent cold cathode tubes are alternately inverted, low noise can be realized. On the other hand, since the high voltage of reverse polarity is applied between the terminals of the adjacent cold cathode tube of the side connected to the high voltage side circuit, the insulation distance between each terminal must be ensured. There is also a problem that the wiring corresponding to the arrangement of the cold cathode tube is attracted, which leads to an increase in the size of the substrate, and has a disadvantage in cost. In addition, the insulation process is required also for wiring of the lamp lead wires for every two cold cathode tubes.

Therefore, the present inventors made further improvements by diligently examining and reached the invention of the inverter circuit and backlight of this invention.

See FIG. 6. 6, the schematic circuit block diagram of the inverter circuit and backlight which concerns on one Example of this invention which concerns on this embodiment is shown. As shown in FIG. 6, an inverter circuit according to an embodiment of the present invention has a high voltage side circuit 410 and a low voltage side circuit 416. The high voltage side circuit 410 is connected to the inverter transformer 411 and the resistance element 412 connected to the secondary side (secondary coil), and to the inverter transformer 413 and its secondary side (secondary coil). Resistive element 414. The low voltage side circuit 416 has a plurality of (n / 2) balance transformers 417_1, 417_2, ..., 417_n / 2.

The backlight shown in FIG. 6 has a plurality (n) of cold cathode tubes 122_1, 122_2, ..., 122_ (n-1), 122_n. Here, although n = 14 and the number of cold cathode tubes 122 was 14, it is not limited to this, Any number may be sufficient as the number of cold cathode tubes 122 is an even number. The cold cathode tubes 122_1 to 122_n are supplied with an AC voltage boosted by the secondary side (secondary coil) of the inverter transformer 411 and 413 of the high voltage side circuit 410, respectively. The resistive elements 412 and 414 become resistances for tube current detection flowing through the cold cathode tubes 122_1 to 122_n.

Referring to Fig. 6, adjacent cold cathode tubes, that is, cold cathode tube 122_1 and cold cathode tube 122_2, cold cathode tube 122_3 and cold cathode tube 122_4, ..., cold cathode tube 122_ (n-1) and cold cathode tube 122_n have the same high pressure Voltage is to be applied. That is, high voltage of reverse polarity is applied to every two cold cathode tubes. For example, the high voltage applied to the cold cathode tube 122_1 and the cold cathode tube 122_2 becomes reverse polarity with the high voltage applied to the cold cathode tube 122_3 and the cold cathode tube 122_4. Similarly, the high voltage applied to the cold cathode tube 122_3 and the cold cathode tube 122_4 becomes reverse polarity with the high voltage applied to the cold cathode tube 122_5 (not shown) and the cold cathode tube 122_6 (not shown). Similarly, high voltages applied to the cold cathode tube 122_ (n-3) (not shown) and the cold cathode tube 122_ (n-2) (not shown) are applied to the cold cathode tube 122_ (n-1) and the cold cathode tube 122_n. Becomes high voltage and reverse polarity. As described above, the inverter circuit and the backlight according to the present invention according to the present embodiment are differentially driven every two cold cathode tubes, thereby achieving low noise.

The adjacent cold cathode tube 122_1 and the cold cathode tube 122_3 are connected in series with the primary side (primary coil) of the balance transformer 417_1 in the low pressure side circuit 416. Similarly, the adjacent cold cathode tube 122_2 and the cold cathode tube 122_4 are connected in series with the primary side (primary coil) of the balance transformer 417_2 in the low pressure side circuit 416. Similarly, the adjacent cold cathode tube 122_ (n-2) and cold cathode tube 122_n are connected in series with the primary side (primary coil) of the balance transformer 417_n / 2 in the low-pressure side circuit 416.

In this way, the configuration in which two cold cathode tubes are connected in series with the primary side primary coil of one balance transformer at one interval is adopted. In addition, the secondary side (secondary coil) of all the balance transformers 417_1, 417_2, ..., 417_n / 2 is connected in series, respectively, and forms the closed loop 419. As shown in FIG.

Thus, since the secondary side (secondary coil) of the balance transformers 417_1, 417_2, ..., 417_n / 2 forms the closed loop 419, the current is flowing through this closed loop 419 is balanced. It flows in common to the secondary side (secondary coil) of transformers 417_1, 417_2, ..., 417_n / 2 and flows to the primary side (primary coil) of balance transformers 417_1, 417_2, ..., 417_n / 2. Balance of the currents iL1, iL2, ..., iLn flowing through the cold cathode tubes 122_1, 122_2, ..., 122_ (n-1), 122_n connected to each other is maintained.

In addition, in the inverter circuit and the backlight of the present invention according to the present embodiment, the number of balance transformers is half of the number of cold cathode tubes.

Further, in the inverter circuit and the backlight of the present invention, the phase of the high voltage applied to the cold cathode tube is reversed for every two cold cathode tubes, in other words, the phase of the high voltage applied to the two adjacent cold cathode tubes is in phase. It is not necessary to consider the insulation distance between these two cold cathode tubes, and the minimum wiring becomes possible. In addition, in the inverter circuit and the backlight of the present invention, it is necessary to secure an insulation distance at the high voltage side for every two cold cathode tubes. However, by using a slit or the like, wiring corresponding to the arrangement pitch of the cold cathode tubes is possible.

In addition, in the inverter circuit and the backlight of the present invention, since the primary side (primary coil) of the balance transformers 417_1, 417_2, ..., 417_n / 2 is low voltage, the wiring normally used may be used.

Moreover, in this embodiment, the phase of the voltage applied to every two cold cathode tubes was reversed, but the inverter circuit and backlight of this invention are not limited to this, For every three cold cathode tubes, Every four etc. Alternatively, the phase of the voltage applied to each of the plurality of lines may be reversed. In order to suppress the noise generated in the cold cathode tube from affecting the display screen as much as possible, it is effective to invert the phases of the adjacent cold cathode tubes at various places where possible, and as shown in FIG. 6, the phase of the voltage applied to each cold cathode tube is shown. Inverting is most suitable for securing an insulation distance and reducing noise.

In this embodiment, another embodiment of the inverter circuit and the backlight of the present invention will be described.

See FIG. 7 shows a schematic circuit configuration diagram of the inverter circuit and the backlight of the present invention according to the present embodiment. The inverter circuit and the backlight of the present invention according to the present embodiment have the same configuration as the inverter circuit and the backlight of the present invention described with reference to the above-described embodiment and FIG. 6, but the inverter circuit of the present invention shown in FIG. 6. The backlight unit has two inverter transformers 411 and 413, and the two resonant circuits are constituted in the present embodiment, in that the inverter transformer 421 is provided in this embodiment. . The inverter transformer 421 uses one coil on the driving primary side and two coils on the secondary side, and uses the coil on the driving primary side in common. By doing in this way, the effect similar to embodiment mentioned above can be acquired. In particular, according to the present embodiment, since the inverter transformer can be realized with one, it has the advantage of miniaturization. Furthermore, in this case, the number of cold cathode tubes in each resonant circuit is preferably the same, and as a result, the total number of cold cathode tubes is preferably even.

Hereinafter, in the inverter circuit and the balance transformer of the present invention, the use of the slit to secure the insulation distance along the high voltage side for every two cold cathode tubes will be described. 8 shows an example in which the slit 430 is used for the electrode substrate 153 on the high voltage side. As shown in FIG. 8, connectors 153_1, 153_2, 153_3, 153_4, 153_5, 153_6, 153_7,..., 153_n that are connected to the cold cathode tube at the high voltage side of the electrode substrate 153 are designed. A negative high voltage is applied to the connectors 153_1, 153_4, 153_5, ..., 153_n, and a positive high voltage is applied to the connectors 153_2, 153_3, 153_6, 153_7, ..., 153_ (n-1). 153a is a negative high voltage line and is formed on the main surface of the substrate 153. 153b is a positive high voltage line and is formed on the back surface of the substrate 153. That is, the positive high voltage line 153b formed on the back surface of the board 153 and the connectors 153_2, 153_3, 153_6, 153_7, ..., 153_ (n-1) designed on the main surface of the board 153 are the board 153. It is connected via the through-hole designed in. By employing the configuration as shown in Fig. 8, by using the slit 430, it is possible to ensure an insulation distance on the high voltage side, and to allow wiring corresponding to the arrangement pitch of the cold cathode tube.

According to the inverter circuit and the backlight of the present invention, even when the number of cold cathode tubes (discharge tubes) is increased, the number of balance transformers can be limited to half the number of cold cathode tubes, so that the backlight can be enlarged.

In addition, according to the inverter circuit and the backlight of the present invention, since the phases of the alternating voltage applied to the adjacent cold cathode tubes are inverted alternately for each of a plurality of lines, it is possible not only to suppress the noise but also to apply the alternating phase voltage of the same phase. It is not necessary to consider the insulation distance between the cold cathode tubes of the plurality of lines, and the wiring can be made compact.

As mentioned above, the inverter circuit and backlight which concern on this invention can be used suitably for a liquid crystal display device. The liquid crystal display device is useful as a display device such as a monitor device or a television receiver in a personal computer, and the inverter circuit is also useful as such a component.

Claims (17)

A plurality of inverter transformers for supplying an AC high voltage in reverse phase to each other; And Including a plurality of balance transformers, The inverter transformer supplies an alternating current high voltage every two cold cathode tubes, The cold cathode tubes are connected in series with the primary windings of the balance transformer at intervals of the cold cathode tubes, and the secondary windings of the plurality of balance transformers are connected in series to form a closed loop. Circuit. delete The inverter circuit of claim 1, wherein the plurality of inverter transformers are two. The inverter circuit according to claim 1, wherein the inverter transformer comprises one primary winding and two secondary windings, wherein the two secondary windings are arranged such that the AC high voltages are reverse polarity with each other. The inverter circuit according to claim 1, wherein terminals for providing an alternating-phase high voltage for each of the plurality of cold cathode tubes are separated by slits. A plurality of cold cathode tubes; A plurality of inverter transformers for supplying alternating high-phase AC high voltages; And, Including a plurality of balance transformers, The inverter transformer supplies an alternating current high voltage every two cold cathode tubes, The cold cathode tube is connected in series with the primary winding of the balance transformer at one interval from the cold cathode and the secondary windings of the plurality of inverter transformers are connected in series to form a closed loop. The primary winding of the i (i is positive integer) th balance transformer is connected in series with the j (j is positive integer) th cold cathode tube and j + 1 cold cathode tube, and a first winding of the i + 1 th balance transformer is connected in series with the j + 2 th cold cathode tube and the j + 3 th cold cathode tube. delete The backlight of claim 6, wherein the plurality of inverter transformers is two. The backlight of claim 6, wherein the inverter transformer comprises one primary winding and two secondary windings, wherein the two secondary windings are arranged such that the AC high voltages are reverse polarity with each other. 7. The backlight of claim 6, wherein terminals for providing an alternating-phase high voltage for every two cold cathode tubes are spaced apart by slits. A display unit having a liquid crystal panel, a data circuit and a gate circuit connected to the liquid crystal panel; A backlight including a plurality of cold cathode tubes, a plurality of inverter transformers, and a plurality of balance transformers; And, A storage container and a top chassis for storing the display unit and the backlight, The inverter transformer supplies an alternating current high voltage every two cold cathode tubes, Wherein the cold cathode tubes are connected in series with the primary windings of the balance transformer at intervals of the cold cathode tubes, and the secondary windings of the plurality of inverter transformers are connected in series to form a closed loop. Device. delete delete delete delete delete delete

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